PPM ViaLiteHD HRx-C-HB-1 series User Manual

ViaLiteHD

C-Band RF Fibre Optic Link

User Guide

HRx-C-HB-1

CR4067 11/03/2019

Pulse Power & Measurement Ltd, 65 Shrivenham Hundred Business Park, Watchfield, Swindon, Wiltshire SN68TY, UK

Tel +44 (0)1793 784389 Fax +44 (0)1793 784391 Email sales@vialite.com Web www.vialite.com

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Instrument Care and Safety Information

Please read the whole of this section before using your ViaLiteHD product. It contains important

safety information and will enable you to get the most out of your Fibre Optic Link.

Electrical Safety

The ViaLiteHD chassis is a Safety Class 1 product (having metal case directly
connected to earth via the power supply cable).

When operating the equipment note the following precautions:
 Hazardous voltages exist within the equipment. There are no user serviceable

parts inside; the covers should only be removed by a qualified technician.

 There are no user replaceable fuses in the chassis mounted equipment.

Replacement should only be carried out by a ViaLite Communications
technician.

 The chassis earth stud SHOULD be connected to the safety earth.
 When using a 2 pin power supply cable the chassis earth stud MUST be

connected to the safety earth.

 The ViaLiteHD Power Supply Modules do not have an isolating switch on the

mains voltage inlet. For this reason, the ViaLiteHD Chassis must be installed
within easy reach of a clearly labelled dual pole mains isolation switch, which
supplies the equipment.

ESD Precautions

The ViaLiteHD RF Fibre Optic Link is equipped with high frequency active
electronics, without the correct handing they will be susceptible to damage.

Precautions for handling electro-static sensitive devices should be observed
when handling all ViaLiteHD modules.

 Technicians should ensure that they use effective personal grounding (i.e.

ESD wrist strap etc.) when servicing the equipment.

 Any equipment or tools used should be grounded to prevent static charge

build-up.

Good practice should be observed at all times for reference see relevant
standards. EN 61340-5-1, “Protection of Electronic Devices from Electrostatic
Phenomena – General Requirements”

Optical Safety

The ViaLiteHD RF Fibre Optic Transmitters contain optical sources (usually laser
diodes) operating at nominal wavelengths of 1270nm to 1610nm.

These devices are rated as EN60825-1:2007 as CLASS 1 radiation emitting
devices. A class 1 laser is safe under all conditions of normal use.

When operating the equipment note the following precautions:
 Never look into the end of an optical fibre directly or by reflection either with

the naked eye or through an optical instrument.

 Never leave equipment with radiating bare fibres – always cap the connectors.
 Do not remove equipment external covers when operating.

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TABLE OF CONTENTS

1 INTRODUCTION ............................................................................................................................. 5

1.1 The C-Band ........................................................................................................................... 5

1.2 Typical deployment ............................................................................................................... 5

1.3 Care of fibre optic connectors ............................................................................................... 5

2 SETTING UP AND UNDERSTANDING THE FIBRE OPTIC LINK ................................................. 6

2.1 Module operation .................................................................................................................. 6

2.1.1 5HP standard plug-in modules ................................................................................... 6

2.1.2 RF connectors ............................................................................................................. 7

2.1.3 Purple link modules ..................................................................................................... 7

2.2 Fibre optic cable & connectors .............................................................................................. 8

2.2.1 Connecting and disconnecting .................................................................................... 8

2.2.2 Cleaning optical connectors, cleaning before every use ............................................ 8

2.2.3 Cleaning optical connectors, high levels of contamination ......................................... 8

2.2.4 FC/APC Connectors ................................................................................................... 9

2.2.5 SC/APC Connectors ................................................................................................. 10

2.2.6 E2000/APC Connectors ............................................................................................ 10

2.2.7 Minimum bend radius................................................................................................ 10

2.3 Using the RF link module .................................................................................................... 11

2.3.1 Connecting the module ............................................................................................. 11

2.3.2 Front panel indicators, plug-in modules .................................................................... 11

2.3.3 LED indicator, purple modules .................................................................................. 11

2.3.4 Module summary alarm ............................................................................................ 11

2.3.5 Connecting to the summary alarm ............................................................................ 12

2.3.6 Received light level (RLL) alarm ............................................................................... 12

2.3.7 Module analogue monitor ......................................................................................... 12

2.3.8 High power and DWDM transmitter modules, thermal load ..................................... 13

2.3.9 Operating in gain control modes ............................................................................... 13

2.4 Controlling RF modules ....................................................................................................... 14

2.4.1 Manual control, MGC ................................................................................................ 14

2.4.2 Manual control, DIP switch functions ........................................................................ 14

2.4.2.1 DIP switches - receiver MGC ..................................................................... 15

2.4.2.2 DIP switches - transmitter MGC ................................................................ 15

2.4.2.3 Manual gain control example ..................................................................... 16

2.4.2.4 DIP switches - control ................................................................................ 16

2.4.3 Changing module RF gain ........................................................................................ 17

2.4.4 Software control - via SNMP controller ..................................................................... 17

2.5 LNA/LNB and BUC DC feeds.............................................................................................. 17

2.5.1 LNA/LNB feed - transmitter modules ........................................................................ 17

2.5.2 LNA/LNB feed efficiency - plug-in modules .............................................................. 17

2.5.3 LNA/LNB voltage boost - plug-in modules ................................................................ 17

2.5.4 LNA feed - Purple link modules ................................................................................ 18

2.5.5 LNA feed – Voltage versus current characteristic .................................................... 18

2.5.6 BUC feed - receiver modules .................................................................................... 18

2.5.7 Manual configuration of LNA/LNB and BUC feeds, plug-in modules ....................... 19

2.6 Module Interface ratings ...................................................................................................... 19

2.6.1 Susceptibility to DC pulses from ViaLiteHD receivers .............................................. 19

2.6.2 Protection of ViaLiteHD equipment from DC pulses ................................................. 19

2.6.3 Logic interface, TTL 5V ............................................................................................. 19

2.6.4 Logic interface, I2C ................................................................................................... 20

2.6.5 Logic interface, Open Drain, output .......................................................................... 20

2.6.6 Power interface, +12V, input..................................................................................... 20

2.6.7 Analogue interface, laser diode bias, output ............................................................ 20

2.6.8 Analogue interface, photodiode received light level, output ..................................... 20

2.6.9 Internally generated LNB power supply and tone ..................................................... 21

2.6.10 RF connectors ........................................................................................................... 21

2.6.11 Optical connections ................................................................................................... 21

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3 SYSTEM INTEGRATION .............................................................................................................. 22

3.1 Link loss budget calculations .............................................................................................. 22

3.2 Optical loss versus gain ...................................................................................................... 22

3.3 Optical loss versus noise figure .......................................................................................... 22

3.4 Gain ..................................................................................................................................... 23

3.4.1 Effect of temperature on gain ................................................................................... 23

3.5 Noise Figure ........................................................................................................................ 24

3.6 Linearity (P1dB compression) ............................................................................................. 24

3.7 Linearity (IP3 intermodulation) ............................................................................................ 24

3.8 Spurious Free Dynamic Range (SFDR) .............................................................................. 25

3.9 Link delay ............................................................................................................................ 26

3.10 RF isolation ......................................................................................................................... 26

3.10.1 RF isolation, plug-in cards ........................................................................................ 26

3.11 Typical system configuration with fixed gain modules ........................................................ 27

3.12 Commissioning of a communications link ........................................................................... 27

4 PART NUMBERING ...................................................................................................................... 28

4.1 Part numbering matrix ......................................................................................................... 28

4.2 Part numbering, DWDM wavelengths ................................................................................. 28

5 MAINTENANCE AND FAULT FINDING GUIDE ........................................................................... 29

6 FCC APPROVAL ........................................................................................................................... 30

7 PRODUCT WARRANTY ............................................................................................................... 31

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1 Introduction

The ViaLiteHD RF Fibre Optic Links (FOLs) are a family of fibre optically coupled link systems designed
for the transmission of RF analogue signals over long distances for the communications market.

ViaLiteHD is a product brand manufactured by Pulse Power and Measurement Ltd (PPM).
ViaLite Communications is a division of Pulse Power and Measurement Ltd (PPM).

This handbook covers the following ViaLiteHD RF Link part numbers:

 C-Band Transmitter modules (electrical – optical converter) with part numbers starting

o HRT-C

 C-Band Receiver modules (optical - electrical converter) with part numbers starting

o HRR-C

For complete information and product familiarisation, this handbook should be read in conjunction with
all other relevant handbooks for your ViaLiteHD system.

1.1 The C-Band

The ViaLiteHD RF Fibre Optic C-Band Links are designed to cover the extended C-Band frequency
range (uplink and downlink) of 3.4 GHz to 7.1 GHz.
Usable performance can be utilised beyond this range encompassing 500 MHz to 8GHz (see the
relevant characterisation data in section 3).

1.2 Typical deployment

A typical system operates as follows.
The user’s RF electrical signal is input to the transmitter module, which contains RF signal conditioning

and laser control circuitry. The module modulates the intensity of a beam of light with the RF signal
which then travels through an optical fibre to the receiver module. The distance between transmitter
and receiver can range from 1m to 100km; distances in excess of 100km can be achieved with more
complex optical transport systems, depending on the system specified. The receiver module converts
the modulated light back into an electrical signal, which is available at the output of the module.

The C-band link is also designed for use in Dense wavelength division multiplexed (DWDM) systems.
In this scenario, multiple links each operating on a different wavelength of light are combined in a
multiplexer and sent down a single optical fibre path. At the receiving end, a de-multiplexer separates
the wavelengths for the corresponding receivers. See section 4.2 for wavelength options when
considering the transmitters. Receiver modules however are wideband and will respond to any
wavelength of light passed to them.

ViaLite Communications offer a design service for complex DWDM requirements including supply of
optical multiplexers, optical amplifiers, optical switches and dispersion compensators. On-site
commissioning and installation support is also available.

1.3 Care of fibre optic connectors

When the fibre optic cables are not connected, it is essential that the cable and equipment connectors
are protected by the dust caps provided with the system. Failure to do so may result in damage to the
fibre ends, which are critical to the system performance. Please refer to section 0 for fibre optic cable
handling details.

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2 Setting up and understanding the fibre optic link

This section describes the connections between your RF fibre optic transmitter (electrical – optical
converter) and receiver (optical - electrical converter) modules, and the operation of both modules in a
system.

Please read fully all relevant documents for information on installing your ViaLiteHD equipment before
commissioning your RF fibre optic link system.

2.1 Module operation

2.1.1 5HP standard plug-in modules

All ViaLiteHD plug-in modules are hot-swappable, so it is not necessary to power-down the chassis
before inserting a module. All standard optical connectors are retained by the module, so it will be
necessary to either disconnect any cables or have a sufficiently long service loop when removing
modules.

To install a 5HP standard module and matching interface plate

 The protective covers on the connectors may be left in place.
 Push the release button of the module handle down and simultaneously pull the top of the handle

towards you.

 Align the module upright and perpendicular to the front face of the chassis so that the PCB slides

into the “crow’s feet” card guides top and bottom.

 Gently push the module down its guide, applying pressure via the handle, you may also apply

pressure between the LED and test connector (where test connector is fitted as these are not
available on all module types).

 As the module is fully mated the top of the handle should snap back and lock in position.
 The pawls of the handle should be fully engaged in the matching slots.
 If power is applied to the chassis the module power LED should light as soon as the module is fully

inserted

 Remove protective covers and connect any interface cables

To remove a 5HP Standard module

 Disconnect any cables if necessary
 Push the release button of the module handle down and simultaneously pull the top of the handle

forwards.

 Apply pressure via the handle and gently withdraw the module from the chassis.

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2.1.2 RF connectors

ViaLiteHD C-Band link products are fitted with 50 Ohm female SMA connectors.
The SMA connector is a semi-precision sub-miniature RF and microwave connector and to maintain

performance up to 8GHz, ensure that when not in use, the supplied RF connector dust caps are fitted.
If any dust or dirt is visible within the connector body, cleaning with compressed air before mating is
advised.
When attaching cables to these RF connectors, a torque wrench should be used to guarantee
tightening to 1.0 Nm.

2.1.3 Purple link modules

The Purple Link is a small, dustproof C-Band RF over fibre module available for both the transmitter
and receiver. The 15-way D-type connector provides connectivity for the Tx or Rx alarms, I2C setup
using the ViaLiteHD Programming Kit(HRx-HD-DEV103) and the external power supply (optional HPS-
CS-4).

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2.2 Fibre optic cable & connectors

All ViaLiteHD RF modules use single-mode (9µm/125µm) cable terminated in a range of optical
connectors detailed below. Cross-site fibre optic cables are available from ViaLite Communications
as either standard patch leads or heavy-duty multicore cables.

Warning!

Angle polished (APC) and standard (PC) connector must not be confused.

The two connector types are not interchangeable and mating one with the other will
damage both the cable and the module connectors.
The specification of optical connector is critical to the performance of the complete
fibre optic link. System performance can only be guaranteed with fibre optic cables
and connectors supplied by ViaLite Communications.

When FC/APC connectors are specified they must be “narrow key width”

2.2.1 Connecting and disconnecting

Before connecting optical fibres to the module or to each other, ensure that the mating connectors are
clean (see below).

2.2.2 Cleaning optical connectors, cleaning before every use

Optical connectors MUST be cleaned before use, even where they have been protected with dust caps.
A large percentage of performance issues can be attributed to dirty fibres.

For more details please read the cleaning instruction which accompanies the connector cleaning kit.
Details can also be found on the CD supplied with your equipment.

2.2.3 Cleaning optical connectors, high levels of contamination

If there are performance issues that are not resolved by basic cleaning, then the following procedure
should be used. If the level of contamination is high it will be necessary to repeat this procedure.

Cleaning items required
 Lint free fibre cleaning tissues and/or cleaning sticks (normal cosmetic tissues produce dust and

are not acceptable).

 Reagent grade Isopropyl Alcohol (IPA).
 Air duster or filtered compressed air line.

Cable Connector Cleaning

 Dampen a patch of cleaning tissue with IPA and clean all surfaces of the plug ferrule.
 Using a dry cleaning tissue, dry the ferrule and clean the end face.

 Peel the plastic cover from an unused ‘N’

cleaning pad.

 Hold the connector between your thumb and

forefinger

 Clean the connector using firm pressure by

swiping in a pendulum motion through each
segment of the ‘N’ shape, following the
diagram

 Do not swipe over the same space twice.

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 Using the air duster, blow away any residue from the end of the connector.
Module Female Receptacle Cleaning (only recommended if problems are being experienced)

 Either use an optical cleaning stick or twist a cleaning tissue to form a stiff probe, moisten either

with IPA. Gently push the probe into the receptacle and twist around several times to dislodge any
dirt.

 Repeat the above process with a dry tissue.
 Using the air duster, blow away any residue from the receptacle.

Important Notes

 IPA is flammable. Follow appropriate precautions / local guidelines when handling and storing.
 IPA can be harmful if spilt on skin. Use appropriate protection when handling.
 It should only be necessary to clean the female receptacles on the modules if problems are being

experienced.

Warning!

Never inspect an optical fibre or connector with the naked eye or an instrument
unless you are convinced that there is no optical radiation being emitted by the
fibre. Remove all power sources to all modules, and completely disconnect the
optical fibres.

2.2.4 FC/APC Connectors

To connect FC/APC optical connectors follow these steps:
 Remove the dust caps and align the white ceramic centre ferrule on the cable connector with the

mating receptacle.

 There is a key (lug) on the side of the ferrule, which must match the keyway (gap) in the receptacle

shroud.

 When they are aligned, gently push the plug home.
 Finger tighten the knurled collet nut onto the threaded receptacle.

To disconnect follow these steps:

 Using fingers fully unscrew the knurled collet nut, gently withdraw the connector.
 Replace the dust caps on both the receptacle and the cable plug.

Warning!

It is possible to tighten the knurled collet without aligning the lug and gap. This
will result in poor light transmission. Check that the lug and gap are aligned
before tightening the knurled collet

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2.2.5 SC/APC Connectors

To connect SC/APC optical connectors follow these steps:

 Remove the plug protective cover.
 Align the connector keyway slot in the adaptor to the key of the plug.
 Gently push the plug-into the adapter until a click is heard and the connector locks.

To disconnect follow these steps:
 Grip the body of the plug and gently pull the plug from the adaptor, replace the protective cover.

Only connect SC/APC cable to SC/APC receptacles.

2.2.6 E2000/APC Connectors

All ViaLiteHD E2000 connectorised modules use E2000/APC. Clean the plug before inserting.
To connect E2000/APC optical connectors:-

 Gently push the plug-into the E2000/APC adapter.
 The cover will automatically disengage.
 Push until a click is heard and the connector locks.

To disconnect:-

 To disconnect, depress the lever at the rear of the connector and withdraw the connector.
 The protective cover automatically engages when removed.

Only connect E2000/APC cable to E2000/APC adaptors.

2.2.7 Minimum bend radius

Because optical fibre is made of glass, it is important not to subject it to excessive stress. For this
reason, each type of cable has a minimum bend radius (MBR) specification, beyond which the cable
cannot be bent without permanent damage occurring. Systems using longer wavelength (i.e. 1550nm)
are less tolerant to small bend radii.

The minimum bend radius of standard SMF28 fibre optic cable fitted to ViaLiteHD modules is 50mm.
MBR specifications for ViaLite Communications supplied fibre optic cables are given in the ViaLite
Classic and ViaLiteHD System Handbooks Lxx-HB and Hxx-HB respectively.

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2.3 Using the RF link module

2.3.1 Connecting the module

Connect the transmitter module to the power source, cross-site fibre optic cable and RF signal as
described in section 2.1. The RF input signal applied to the signal connector should be within the
maximum and minimum signal levels given in the datasheet.

2.3.2 Front panel indicators, plug-in modules

Each plug-in module has three front panel LEDs for indication of the state of the module. The following
table shows the operation of the front panel LEDs which are dependent on module type.

Colour

Plug-in

Transmitter

Plug-in

Receiver

LED1

GREEN

NORMAL

Flashing GREEN

Programming

Programming

RED

Not used

Not used

No light

TX PSU fail

RX PSU fail

LED2

GREEN

NORMAL

Flashing RED fast

TX Alarm

Not used

Flashing RED slow

Not used

RX Alarm

RED

Not used

Not used

LED3

GREEN

I2C enabled

Flashing GREEN

I2C active

AMBER

I2C disabled

2.3.3 LED indicator, purple modules

These modules are fitted with a single LED for indication of the state of the module.

2.3.4 Module summary alarm

Each module has a single summary alarm, which registers the status of the module. Activation of this
alarm registers an internal fault and the module should be replaced with a spare and returned to your
local ViaLiteHD representative. The alarm state should be accompanied by a fault status on one of the
front panel status LEDs.

The summary alarm is indicated by use of open drain logic. The alarm logic is OPEN when in an
ALARM state and SHORT when in a NORMAL (non-alarm) state. The module will remain in an ALARM
state until the ALARM condition is cleared, there is no latching.

Colour

Blue

link

Yellow

link

LED

GREEN

Normal

RED

Alarm

No Light

No power

LED1

LED2

LED3

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2.3.5 Connecting to the summary alarm

The alarm output pin should be connected to a suitable current source (a positive voltage via a 10kohm
pull-up resistor is adequate). When the module is in a working (non-alarm) state, the alarm output pin
is short circuited to ground by the module. If the module enters an alarm state, the alarm pin is released
to a high impedance state and current is no longer drawn from the constant current source. In the case
of a positive voltage and pull-up resistor, the voltage on the alarm output pin will rise to indicate the
alarm state. It follows that, if a module is removed from the chassis, the alarm will be raised for that
module position.

The capability of the open collector is dependent on the module that provides it. The typical capability
of the Open Collector/Drain is 50mA maximum current sink and 15V maximum voltage (Vext).

Note: Modules fitted in a chassis may have their alarm lines pull up by other chassis equipment, such
as switch, splitter, summary alarm or SNMP and web controller modules.

2.3.6 Received light level (RLL) alarm

Receiver modules, monitor the average incoming received light level (RLL), if the power drops below
a pre-set threshold the module will generate an RLL alarm.

 The RLL alarm threshold is set for a nominal input power of -15.0dBm

o Nominal optical loss of 25.0dB @ 10.0dBm (10mW) TX

Under normal operating conditions the RLL alarm accuracy is +/-2dB; and +/-4dB under extreme
conditions.

2.3.7 Module analogue monitor

Each plug-in module has either one or two analogue monitor ports. These allow simple DC indication
of the status of either lasers or photodiodes fitted in the RF modules. The analogue monitor is available
on the chassis connector, see the chassis handbook. The analogue monitor functions are dependent
on the type of module. The monitor function(s) provided are shown in the table below.

Function

Single Transmitter

Single Receiver

Analogue monitor A

Not Used

Received light level

Analogue monitor B

Laser bias monitor

Not Used

Vext

Pull up
Resistor

Alarm

Ground

Internal to module External to module

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The performance of the analogue monitors is as follows

Monitor type

Operation

TX analogue,
current monitor
output

V

IFL

= 25 x I

FWD

V

IFL

= Voltage output of the current monitor, in volts

I

FWD

= Average bias current of laser diode, in amps

Note: Normal operating range I

FWD

is 0 – 120mA

RX analogue,
received light level
output

V

RLL

= 4.00 – [ 0.15 x ( 10.0 - P

OPT

) ]

V

RLL

= Voltage output of the received light level (RLL) monitor, in volts

P

OPT

= Optical input power, in dBm

Note: Optical transmitter power is assumed to be +10dBm

2.3.8 High power and DWDM transmitter modules, thermal load

All DWDM modules have active thermal control to stabilise their laser operating wavelength. This
requirement produces additional heat loading in their deployed environments. For this reason extra
consideration is needed when planning the installation and deployment of these systems.
If the installed environment temperature is uncontrolled, there exists the possibility that at high
temperature, operating efficiency will be reduced. Furthermore, if the active thermal control is unable to
maintain laser operating temperature, a major alarm and module shutdown will ensue.

To maintain full operational temperature and efficiency we suggest that you take the following actions.

 Do not place DWDM transmitters adjacent to each other
 When using a 3U chassis if more than 4 modules are fitted, forced air cooling should be used (flow

rate ~100CFM or more)

 If housing DWDM transmitters in an outdoor housing contact ViaLite Communications for more

details

2.3.9 Operating in gain control modes

Modules can be operated in four different gain control modes when operated with an SNMP and Web
controller module (ViaLiteHD part number HRC-3).
The SNMP and Web controller module is required for configuring the AGC modes which operate by
varying the RF gain of the card in 0.5dB steps in response to measurements of either optical or RF
power.
Manual control is also available; this can be set using the hardware DIP switches.

For more information on this feature, please see section 2.13 of the ViaLiteHD SNMP controller
handbook, HRC-3-HB.

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2.4 Controlling RF modules

ViaLiteHD RF links are factory set and ready to operate. However, they can be software controlled
(where an SNMP module is used in the same chassis) or manually controlled via the DIP switches fitted
on each module.

2.4.1 Manual control, MGC

The plug-in modules can be manually configured to set various operational parameters. The dual in
line package (DIP) switches SW1, SW2, SW3 control configuration and are located on the bottom side
of the PCB. These switches can be accessed by withdrawing the module by approximately one-third
of its length. Two sets of switches will be installed depending on the type of module. Details of the
function of each switch are given in the section below.

2.4.2 Manual control, DIP switch functions

Located on the bottom side of the module board, three DIP switches (SW1 to 3) provide manual control
of various functions. SW1 and SW2 are dedicated to manual gain control (MGC). Once TX_MGC_ON
or RX_MGC_ON is switched on, internal RF attenuators can be set directly to a desired level. SW3 is
used to control various common control functions.

All intelligent modules will be delivered with DIP switches all set to OFF (clear). Only special manual
gain control modules will be delivered with the DIP switches set to factory calibrated gain settings.

Single Transmitter

Single Receiver

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SW1 Top DIP switch bank

Single transmitter HRT

Single receiver HRR

Not fitted

RXMGC

Not fitted

RX – 0.5dB

Not fitted

RX – 1dB

Not fitted

RX – 2dB

Not fitted

RX – 4dB

Not fitted

RX – 8dB

SW2 Middle DIP switch bank

Single transmitter HRT

Single receiver HRR

TXMGC

Not fitted

TX – 0.5dB

Not fitted

TX – 1dB

Not fitted

TX – 2dB

Not fitted

TX – 4dB

Not fitted

TX – 8dB

Not fitted

SW3 Bottom DIP switch bank

Single transmitter HRT

Single receiver HRR

TX rst

TX rst (not used)

RX rst (not used)

RX rst

SNMP dis

SNMP dis

Tone

Tone (not used)

VSEL

VSEL (not used)

LNB

LNB (not used)

TXAGC

TXAGC(not used)

RXAGC (not used)

RXAGC

When viewed in the orientation illustrated, switching the DIP to the LEFT is OFF (clear) and to the
RIGHT is ON (set)

2.4.2.1 DIP switches - receiver MGC

The RF gain within the receiver function is the sum of all gain settings on SW1. The RF gain can be
changed in nominal steps of 0.5dB.
For special manual gain control modules record the factory setting of each gain step; this is the preset
gain of the receiver.

 RXMGC ON = Manual gain control, OFF = Software control or at default setting
 RX – 0.5dB ON = Gain increased by 0.5dB nominal, OFF= no gain increase
 RX – 1dB ON = Gain increased by 1dB nominal, OFF= no gain increase
 RX – 2dB ON = Gain increased by 2dB nominal, OFF= no gain increase
 RX – 4dB ON = Gain increased by 4dB nominal, OFF= no gain increase
 RX – 8dB ON = Gain increased by 8dB nominal, OFF= no gain increase

When MGC is not in use, manual attenuation has to be set to zero, i.e. all poles with the same switch
should return to OFF position. Failure to do so may prevent the module from controlling the gain
correctly.

2.4.2.2 DIP switches - transmitter MGC

The RF gain within the transmitter function is the sum of all attenuator settings on SW2. The RF gain
can be changed in nominal steps of 0.5dB.
For special manual gain control modules record the factory setting of each gain step; this is the preset
gain of the transmitter.

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 TXMGC ON = Manual gain control, OFF = Software control or at default setting
 TX – 0.5dB ON = Gain increased by 0.5dB nominal, OFF= no gain increase
 TX – 1dB ON = Gain increased by 1dB nominal, OFF= no gain increase
 TX – 2dB ON = Gain increased by 2dB nominal, OFF= no gain increase
 TX – 4dB ON = Gain increased by 4dB nominal, OFF= no gain increase
 TX – 8dB ON = Gain increased by 8dB nominal, OFF= no gain increase

When MGC is not in use, manual attenuation has to be set to zero, i.e. all poles with the same switch
should return to OFF position. Failure to do so may prevent the module from controlling the gain
correctly.

2.4.2.3 Manual gain control example

In this example we consider a receiver. The factory set values will typically be in the mid-range of the
allowable gain setting range, to allow the operator to both increase and decrease the gain of the unit if
desired.

 Factory preset: TX–0.5dB =ON; TX–1dB =OFF; TX–2dB =ON; TX–4dB =ON; TX–8dB =OFF.
 This is a total gain of 0.5 + 2 + 4 = 6.5dB [this will be the factory preset gain]

The operator wishes to increase the gain by 3dB from factory preset gain, he must increase the DIP
switch set gain from 6.5dB to 9.5dB

 The new gain setting desired will be 9.5dB, made from the following steps 0.5 + 1 + 8, therefore set

the switches as shown below

 TX – 0.5dB = ON; TX – 1dB = ON; TX – 2dB = OFF; TX – 4dB = OFF; TX – 8dB = ON.
 The new gain is now set to 9.5dB

Note: The gain of the link is the sum of the transmitter module and receiver module gains.

2.4.2.4 DIP switches - control

If you wish to use manual control we advise that you record the initial setting of each switch, this is the
preset configuration of the module. SW3 control functions are common to the whole module. The on­board micro controllers can be manually reset by using TX_RESET and/or RX_RESET, they must
return to the OFF (clear) position to initiate the actual reset sequence.

Switching on SNMP_dis will disable the module I2C bus for that module. In this case, SNMP controller
or other I2C hosts will be unable to talk to the module.

RF auto gain control (AGC) function can be activated by setting TX_AGC_ON and RX_AGC_ON to ON
(set) position. However, AGC mode will be overridden by MGC mode if both modes are selected. These
will override module internal soft gain control. Some modules will have control functions indicated that
are not used, such as RX_rst in a single transmitter module. Switches for these “not used” positions
should always be left in the OFF (clear) position.

 TX rst Reset TX microcontroller by moving switch from OFF > ON > OFF, ensure that it is

returned to the OFF position**

 RX rst Reset RX microcontroller by moving switch from OFF > ON > OFF, ensure that it is

returned to the OFF position**

 SNMP_dis ON = I2C bus disabled (module cannot be remotely accessed), OFF = I2C bus enabled
 Tone ON = 22kHz tone present, OFF = 22kHz tone disabled
 VSEL ON = Internal module LNB PSU voltage set to 18V, OFF = Internal module LNB PSU

voltage set to 13V

 LNB ON = Internal module LNB PSU enabled, OFF = Internal module LNB PSU disabled
 TXAGC* ON = TX AGC control function activate, OFF = TX AGC control function disabled
 RXAGC* ON = RX AGC control function activate, OFF = RX AGC control function disabled

* Not available on manual control modules
** Card must be powered to perform the reset action, removing power will also reset a module

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17

2.4.3 Changing module RF gain

The link performance specifications apply when modules are operated in the factory preset
configuration. However, the gain of the modules can be changed to suit customer requirements.

The performance of the transmitter is highly dependent on the laser diode. Changing transmitter and
receiver gain will affect the sensitivity and linearity of the module. Detail of these effects are provided
in section 3.

2.4.4 Software control - via SNMP controller

ViaLiteHD RF links can be controlled via a ViaLiteHD SNMP control module when fitted in the same
chassis, see the SNMP controller module handbook for further details. The SNMP module offers control
via both a web interface and SNMP.

Remember if you wish to use software control the manual attenuation has to be set to zero, i.e. all poles
of the switch should return to the OFF position. Failure to do so may prevent the module from controlling
the gain correctly.

2.5 LNA/LNB and BUC DC feeds

The C-band modules have an option to present a DC voltage at the RF connector to power any
connected equipment capable of receiving its power this way.

Warning!

Precautions must be taken to ensure that any connected equipment is tolerant
of the DC voltages supplied.

2.5.1 LNA/LNB feed - transmitter modules

Transmitter modules may be used to provide a power feed via the RF connection to a preceding low
noise amplifier (LNA) or low noise block down converter (LNB).
The voltage source for this function can be supplied externally via a chassis connection or from the
module’s on-board voltage generator

The external DC paths (option 3) of a module may be accessed via the chassis connector for plug-in
modules (see your chassis handbook) or the 15 way D-Type connector for the purple modules.
The LNA/LNB option can be determined from the part number.

Modules in this range offer a variety of feed options, shown below.

0

No LNA feed

1

Internally generated +5 ± 0.5V at 80mA

2

Internally generated +12 ± 1V at 300mA

3

External Feed from chassis connector 0 to +28V at 350mA

5

Internally generated +13.4 ± 1 or +18.5 ± 1 selectable 350mA (up to 7.1GHz)

L

Internally generated +13.4 ± 1 or +18.5 ± 1 selectable 700mA (up to 6.0GHz)

2.5.2 LNA/LNB feed efficiency - plug-in modules

The power consumption of a transmitter is specified without allowance for LNA/LNB power. When
calculating power consumption the module efficiency of the LNA/LNB power supply at full load is 89%
typically and 80% minimum

2.5.3 LNA/LNB voltage boost - plug-in modules

The output voltage of any module equipped with an internal 13/18/22 volt power supply (option “5” and
“L”) can have its output voltage increased to allow for cable losses, the output voltage is increased by

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18

+1V nominally. This is implemented using the modules software configuration. This option is NOT
available on units equipped with +5V, +12V or external voltage feeds.

2.5.4 LNA feed - Purple link modules

Modules in this range offer an internally generated +5V or +12V feed and external feed only.

2.5.5 LNA feed – Voltage versus current characteristic

The LNA voltage is fed via a wideband choke (providing RF isolation) a low value resistor (used for
current monitoring) and a resettable fuse (providing protection). These elements add a series
impedance of approximately one ohm. The graph below shows how the voltage current characteristic
of a typical module with 12 volts fed to into the LNA feed via an external feed from the module connector
“LNA feed” pin.

When using LNA/LNB feeds care must be taken to allow for voltage drops through the input feed
network as well as voltage drops in the output feed network. For example RG58 may have a resistance
of up to 0.2 ohms per meter; this varies greatly between different types and constructions of cable.

Voltage measured at RF connector versus load current, input voltage 12V

NOTE: the graph shows the module operating beyond its specification limit to illustrate the margin of
safe operation, it should not be operated beyond its specification limit.

2.5.6 BUC feed - receiver modules

Receiver modules may optionally provide block up converter (BUC) power feeds. These provide a DC
path to the receiver RF output to provide power to a BUC or other connected module. The external DC
paths (option 3) of a module may be accessed via the chassis connector for Plug-in modules (see your
chassis handbook).

0

No LNA feed

1

Internally generated +5 ± 0.5V at 80mA

2

Internally generated +12 ± 1V at 300mA

3

External Feed from chassis connector 0 to +28V at 350mA

5

Internally generated +13.4 ± 1 or +18.5 ± 1 selectable 350mA (up to 7.1GHz)

L

Internally generated +13.4 ± 1 or +18.5 ± 1 selectable 700mA (up to 6.0GHz)

11.3

11.4

11.5

11.6

11.7

11.8

11.9

12

12.1

0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9

Voltage at RF connector (V)

Load Current (A)

LNA feed –Voltage versus current

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19

2.5.7 Manual configuration of LNA/LNB and BUC feeds, plug-in modules

Some modules can be configured either by jumper or by switch to provide an LNA/LNB or BUC feed
either from an internally generated voltage or from the rear connector in the ViaLiteHD chassis. The
diagram below shows how these are set.

Units with LNA/ LNB internal power supplies (options 1, 2, and 5) will be delivered set to “internal”.
Units with external LNA power (option 3) will be set to “external”. Units with no LNA/LNB or BUC feed
(option 0) will normally have no headers fitted to positions J15 or J16.

Manual configuration of LNA/LNB/BUC DC power feeds

2.6 Module Interface ratings

2.6.1 Susceptibility to DC pulses from ViaLiteHD receivers

All receiver modules will create a 1-2Vpeak DC transient from the RF output at start up into a 50Ω load

(approximately 5V into a 1MΩ load). This may cause failure in some very sensitive spectrum analysers

or similar equipment. Please check before connecting your equipment. Contact ViaLite
Communications for more details.

2.6.2 Protection of ViaLiteHD equipment from DC pulses

All modules have AC coupled inputs and/or outputs and will be sensitive to large transients (>5V)
applied at the RF connector. This may result in permanent damage to the modules, particularly to low
frequency or wideband modules. DVB-T and L-Band HTS modules are designed to survive non
repetitive DC pulse of up to 36V. To increase protection, BUC feed option “B” can be specified for GPS
receiver modules to increases their robustness to DC pulses see section 2.5.6. Contact ViaLite
Communications for more details.

2.6.3 Logic interface, TTL 5V

Absolute maximum voltage rating -0.5 to +5.5V No damage
Input, Logic Low (max) <0.8V
Input, Logic High (min) >2.0V
Output, Logic Low (max) <0.4V no load
Output, Logic High (min) >4.8V no load

Drive capability 1k ohms
Short circuit protection No

J4 (LNB)

up = external
down = internal
open = not connected

RX

J10 (BUC)

up = external
down = internal

open = not connected

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20

2.6.4 Logic interface, I2C

Absolute maximum voltage rating -0.3 to +5.3V No damage
Input, Logic Low (max) <1.5V
Input, Logic High (min) >3.5V

Output, Logic Low (max) <0.6V no load
Output, Logic High (min) >4.3V no load

Drive capability 1k ohms
Short circuit protection No

2.6.5 Logic interface, Open Drain, output

For details of operation see 2.6.3
Operational pull up voltage 0 to 15V No damage

Maximum load current 50mA
Short circuit protection No

Note: Negative voltage on the output will be clamped by the FET body diode; you must ensure that
these do not exceed current rating.
Note: When fitted in a chassis with a controller card (i.e. SNMP and web controller or summary alarm

card) the alarm lines maybe loaded and pulled up, see chassis handbook

Note: When fitted in a chassis or enclosure adjacent to a RF switch or RF splitter card, alarm lines

maybe loaded and pulled up, see chassis handbook

2.6.6 Power interface, +12V, input

Nominal input voltage 12V
Maximum operational voltage range 11.5 to 13V

2.6.7 Analogue interface, laser diode bias, output

For details of operation see 2.6.7
Typical output voltage 1.25V for 50mA bias current

Typical output voltage range 0 to 2.5V
Maximum output voltage range -5 to +5V
Short circuit protection No

2.6.8 Analogue interface, photodiode received light level, output

For details of operation see 2.6.8
Typical output voltage 4.0V at 10 dBm optical input power

Typical output voltage range 1 to 4V
Maximum output voltage range 0 to +5V
Short circuit protection No

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21

2.6.9 Internally generated LNB power supply and tone

Voltage set to LOW
Nominal output voltage 13.4V, Output select = LOW
Output voltage range 12.4 to 14.4V
Current rating 700mA per channel for single transmit channel
Short circuit protection Yes

Voltage set to HIGH
Nominal output voltage 18.5V, Output select = HIGH
Output voltage range 17.5 to 19.5V
Current rating 700mA per channel for single transmit channel
Short circuit protection Yes
Voltage BOOST active
Nominal output Voltage increased 1V, Output boost = ENABLE

Voltage when set to AUX
Nominal output voltage 22V, AUX mode = ON
Output voltage range 21 to 23V
Current rating 150mA per channel for single transmit channel
Short circuit protection Yes
TONE active
Nominal output level 0.6Vp-p, Tone Gen = ACTIVE
Output range 0.4 to 1.2Vp-p
Nominal frequency 22kHz
Frequency accuracy 20 to 24 kHz

2.6.10 RF connectors

Maximum RF input power, no damage +13 dBm continuous, 25 dBm (5 min max)
Maximum usable input power Gain Setting Dependent (+1 dBm to -15 dBm typ)
Maximum RF output power +15 dBm typ

2.6.11 Optical connections

Maximum optical input power, no damage +16 dBm
Maximum usable input power +10 dBm
Optical output power +10 dBm typical for 10mW Transmitter

HRX-C-HB-1 C-BAND LINK HANDBOOK

22

3 System integration

3.1 Link loss budget calculations

The link gain (transmitter RF input level to receiver RF output level) depends on the following factors:

 Optical loss (due to connector insertion loss and optical fibre loss).
 Transmitter gain setting.
 Receiver gain setting.

The actual link gain can be determined as follows:

Link gain = Transmitter Gain + Receiver Gain – (2 x optical loss) [dB]

(Where optical loss = connector insertion losses + fibre losses)

3.2 Optical loss versus gain

The additional electrical insertion loss in dB resulting from optical losses is equal to 2 times that of the
optical loss in dB. This is due to the physics of the optical-to-electrical conversion process in the
receiver. For example, a 1dB increase in optical insertion loss will result in a 2dB decrease in RF signal
at the output of the optical receiver.
For single-mode fibre (e.g. SMF28), the optical loss at the 1310nm operating wavelength of the
ViaLiteHD link is 0.4dB/km. For 1550nm operating wavelength, the optical loss is 0.2dB/km.
This can increase if the fibre is under excessive tension, compression or is bent into a small radius.
For clean, undamaged single-mode connectors, optical insertion loss is typically 0.2dB per interface.

Note: The losses at the optical connections of the transmitter and receiver are allowed for during
manufacture of the module, and may be ignored during link gain calculations.
For short links (<250m) containing no additional optical connectors, and in which the fibre is not subject
to any strain, the optical path loss can be ignored.

3.3 Optical loss versus noise figure

As the optical loss increases there will be a corresponding increase in noise, the chart below shows the
approximate relationship of optical loss to noise figure increase for a standard L-Band HTS link. Below
are graphs that shows the change in noise figure of some popular link types. For links with high power
transmitters see section 0.

Note: If you operate the ViaLiteHD modules in RLL AGC mode it is possible to mask optical loss
variations, but this is not always desirable.

0

5

10

15

20

25

30

35

0 2 4 6 8 10 12 14 16 18 20

Noise Figure Increase (dB)

Optical link loss (dB)

Noise Figure increase vs Optical link loss

5km @1310nm

10km @1550nm

15km @1310nm
30km @1550nm

25km @1310nm

50km @1550nm

35km @1310nm
70km @1550nm

HRX-C-HB-1 C-BAND LINK HANDBOOK

23

3.4 Gain

The Gain of a ViaLiteHD C-Band Link is generally consistent with frequency in the designated downlink
and uplink bands. Useable gain and performance can be found in a wide range from 500MHz to 8 GHz.
Below is the data for a High Gain link pair (TX=0dB, RX=15dB)

3.4.1 Effect of temperature on gain

The gain of a ViaLiteHD C-Band Link generally reduces as temperature increases. The graph below
shows change in RF gain versus the room temperature gain.

-6.00

-5.00

-4.00

-3.00

-2.00

-1.00

0.00

1.00

2.00

0 1000 2000 3000 4000 5000 6000 7000 8000 9000

Response (dB)

Frequency (MHz)

ViaLite Link: Frequency response

-1.5

-1.0

-0.5

0.0

0.5

1.0

1.5

-30 -20 -10 0 10 20 30 40 50 60

Link Gain deviation @ 5GHz (dB)

Temperature (°C)

Link gain vs Temperature

HRX-C-HB-1 C-BAND LINK HANDBOOK

24

3.5 Noise Figure

The noise Figure of a ViaLiteHD C-Band Link generally increases with frequency resulting in a lower
noise figure for the downlink than the uplink. The nominal Noise Figure can be raised or lowered as a
trade off with linearity when commissioning a system to best align with the signal levels present.
Below is the data for a High Gain link pair (TX=0dB, RX=15dB)

3.6 Linearity (P1dB compression)

The P1dB Compression point of a ViaLiteHD C-Band Link is generally consistent with frequency.
The nominal P1dB compression point can be raised or lowered as a trade-off with noise figure when
commissioning a system to best align with the signal levels present.
Below is the data for a High Gain link pair (TX=0dB, RX=15dB)

3.7 Linearity (IP3 intermodulation)

The IP3 Compression point of a ViaLiteHD C-Band Link is generally consistent with frequency.
The nominal point can be raised or lowered as a trade-off with noise figure when commissioning a
system to best align with the signal levels present.
Below is the data for a High Gain link pair (TX=0dB, RX=15dB)

0.0

5.0

10.0

15.0

20.0

25.0

30.0

35.0

0 1000 2000 3000 4000 5000 6000 7000 8000

Noise Figure (dB)

Frequency (MHz)

ViaLite Link: Noise Figure

-15.0

-13.0

-11.0

-9.0

-7.0

-5.0

-3.0

-1.0

1.0

0 1000 2000 3000 4000 5000 6000 7000 8000

P1dB Compression (dBm)

Frequency (MHz)

ViaLite Link: Compression P1dB

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25

3.8 Spurious Free Dynamic Range (SFDR)

The SFDR of a ViaLiteHD C-Band Link is generally lower at higher frequencies due to the impact of
the Noise Figure increasing with frequency.
When altering the gain of the transmitter in order balance the link Noise Figure and linearity, the SFDR
is largely unaffected.
Below is the data for a High Gain link pair (TX=0dB, RX=15dB)

0.0

1.0

2.0

3.0

4.0

5.0

6.0

7.0

8.0

9.0

0 1000 2000 3000 4000 5000 6000 7000 8000

Input IP3 (dBm)

Frequency (MHz)

ViaLite Link: IP3

96

98

100

102

104

106

108

110

112

0 1000 2000 3000 4000 5000 6000 7000 8000

SFDR (dB)

Frequency (MHz)

ViaLite Link: SFDR

HRX-C-HB-1 C-BAND LINK HANDBOOK

26

3.9 Link delay

The ViaLiteHD link introduces a small amount of delay to the system, similar to the contribution of an
amplifier. The typical delay contribution is shown below. You should also account for delay through
RF and fibre cables as these are likely to be much higher than the delay in the link fibre optic modules.

 Fibre optic link transmit and receive pair 13.5ns
 Fibre optic cable 5ns per meter, check manufactures specification
 RF cable 3.5– 5.5 ns per meter dependent on cable type.

LMR-195 4.0 ns per meter
LMR-400 3.9 ns per meter
LMR-500 3.9 ns per meter
LMR-600 3.9 ns per meter
RG-58 5.1 ns per meter, dependent on dielectric
RG-59 4.1 ns per meter, dependent on dielectric
RG-213 5.1 ns per meter
RG-316 4.2 ns per meter

Delays quoted are typical for these cable types, construction of cables of the same type will vary
between manufacturers (i.e. foam/ PTFE/ solid polyethylene dielectric). If delay is critical please check
your manufacturer’s cable specification or electrically test the cables.

3.10 RF isolation

ViaLiteHD cards are designed to offer excellent isolation between slots in a chassis mounted system.
The sensitive components and RF circuitry of ViaLiteHD C-band link modules are well shielded

3.10.1 RF isolation, plug-in cards

Measurements of two C-Band links in adjacent slots of a ViaLiteHD 3U chassis show better than 60dB
isolation.

-120

-100

-80

-60

-40

-20

0

0 1000 2000 3000 4000 5000 6000 7000 8000

Isolation (dB)

Frequency (MHz)

C-Band Chassis Link to Link Isolation

Tx1_Rx2_Rx1
Tx1_Rx2

HRX-C-HB-1 C-BAND LINK HANDBOOK

27

3.11 Typical system configuration with fixed gain modules

The diagram below illustrates a typical communications system configuration.

The link gain for the fixed gain systems depends solely on the optical fibre loss from transmitter to
receiver. There is a Received Light Level (RLL) analogue monitor output on the receiver modules which
can be used to measure the light from the transmitter reaching the receiver during operation.
The RLL threshold alarm (which is triggered when the RLL drops below a preset level) can be used to
determine if the optical link has been damaged or degraded.

3.12 Commissioning of a communications link

This commissioning procedure illustrates the processes required to install and set up a communications
link with gain control. The example describes the commissioning of a C-Band HTS inter-facility link.

We will be considering the installation of the following system.

A LNA provides an output signal in the C- band. The signal must be conveyed over 1500m of fibre,
through a bulkhead at each station, to the modem. An alarm must trigger if the optical path is damaged.

1. Install the link, connecting all optical patch cords and cross-site fibre optic cables. Clean ALL optical

connectors BEFORE mating with the modules.

2. Power up the equipment and allow 15 minutes to warm up.

3. Ensure that the RF power into the transmitter module is set to optimum for your system. Use a

broadband RF power meter for this measurement. Typically this is the input level at which the link’s

intermodulation distortion (IMD) is ~ -40dBc. This value of input power can be calculated from your
datasheet, it is typically 8dB less than the input P1dB.

4. Calculate the approximate optical attenuation in the fibre path. In our case, we have two bulkhead

connectors @ 0.2dB each, 1500m of optical fibre @ 1310nm = 0.6dB, giving a total of 1dB of optical
loss. The total RF gain of the system should be the nominal link gain minus 2x the optical loss.

5. Confirm that the RF output from the receiver is correct (to within measurement accuracy). If the

loss is much higher (> 3dB) than calculated, the most likely explanation is dirt on the optical
connectors. If this is the case, clean each connection in turn until the required system gain is
restored.

Modem

ViaLiteHD chassis

Cable Termination box

Patch cables

SSPA and LNA

Patch cables

Cable Termination box

ViaLiteHD chassis

Cross site cable

Cross site cable

RF feeds for Antenna

HRX-C-HB-1 C-BAND LINK HANDBOOK

28

4 Part numbering

4.1 Part numbering matrix

Note: Options are dependent on module type.
Not all combinations of options are available.

Contact ViaLite Communications for more details.

4.2 Part numbering, DWDM wavelengths

Frequency Wavelength Frequency Wavelength Frequency Wavelength Frequency Wavelength

(GHz) (nm) (GHz) (nm) (GHz) (nm) (GHz) (nm)

C16

191600 1564.6788

C28

192800 1554.9401

C40

194000 1545.3219

C52

195200 1535.8220

H16

191650 1564.2706

H28

192850 1554.5370

H40

194050 1544.9238

H52

195250 1535.4287

C17

191700 1563.8626

C29

192900 1554.1340

C41

194100 1544.5258

C53

195300 1535.0356

H17

191750 1563.4548

H29

192950 1553.7313

H41

194150 1544.1280

H53

195350 1534.6427

C18

191800 1563.0472

C30

193000 1553.3288

C42

194200 1543.7305

C54

195400 1534.2500

H18

191850 1562.6399

H30

193050 1552.9265

H42

194250 1543.3331

H54

195450 1533.8575

C19

191900 1562.2327

C31

193100 1552.5244

C43

194300 1542.9360

C55

195500 1533.4653

H19

191950 1561.8258

H31

193150 1552.1225

H43

194350 1542.5390

H55

195550 1533.0732

C20

192000 1561.4191

C32

193200 1551.7208

C44

194400 1542.1423

C56

195600 1532.6813

H20

192050 1561.0125

H32

193250 1551.3193

H44

194450 1541.7457

H56

195650 1532.2896

C21

192100 1560.6062

C33

193300 1550.9180

C45

194500 1541.3494

C57

195700 1531.8981

H21

192150 1560.2001

H33

193350 1550.5170

H45

194550 1540.9533

H57

195750 1531.5068

C22

192200 1559.7943

C34

193400 1550.1161

C46

194600 1540.5573

C58

195800 1531.1157

H22

192250 1559.3886

H34

193450 1549.7155

H46

194650 1540.1616

H58

195850 1530.7248

C23

192300 1558.9831

C35

193500 1549.3150

C47

194700 1539.7661

C59

195900 1530.3341
H23 192350 1558.5779 H35 193550 1548.9148 H47 194750 1539.3708 H59 195950 1529.9436
C24

192400 1558.1729

C36

193600 1548.5148

C48

194800 1538.9757

H24

192450 1557.7680

H36

193650 1548.1149

H48

194850 1538.5807

C25

192500 1557.3634

C37

193700 1547.7153

C49

194900 1538.1860

H25

192550 1556.9590

H37

193750 1547.3159

H49

194950 1537.7915

C26

192600 1556.5548

C38

193800 1546.9167

C50

195000 1537.3972

H26

192650 1556.1508

H38

193850 1546.5177

H50

195050 1537.0031

C27

192700 1555.7471

C39

193900 1546.1189

C51

195100 1536.6092

H27 192750 1555.3435 H39 193950 1545.7203 H51 195150 1536.2155

Note
Channel numbers beginning with C are on ITU 100GHz grid
Channel numbers beginning with H are on ITU 100GHz offset

Channel

Channel

Channel

Channel

HRX-C-HB-1 C-BAND LINK HANDBOOK

29

5 Maintenance and fault finding guide

Refer to the following table that gives a list of commonly encountered problems and suggested
solutions.

Fault

Possible Causes

Solution

Power LED does
not illuminate.

Power is not connected to
the PSU.

Module is not fully inserted.

Connect mains power to the rear of the PSU.
Check fuses of power leads.

Check module is properly aligned and handle
pawls are fully engaged.

Check there are no obstructions to the rear
such as optical cable protective covers.

Difficulty inserting
module.

Incorrect alignment.

Incorrect module slot.

Check that the module is correctly fitted in
card guides.

Check that module is in correct slot.
Slots 1-13 for 5HP modules.

Alarm LED in
ALARM state.

LNA Feed is in current limit.
Laser degraded.
Low optical level at receiver.

Check external load.
Return to local ViaLite Communications

office.
Check optical link for breaks / kinks.

Check all optical connectors are clean.

Low signal level.

Gain adjustment set too low.
RF feed not connected.
Optical loss too high.
Incorrect optical connectors

Incorrect manual or software
gain settings

Input power too high

Increase gain setting.
Check RF connections.
Clean and check Optical connections.
Ensure that optical cable matches the type of

connectors on you ViaLiteHD module,
normally cable and connector colours should
match.

Reset to factory default.
Or reset to known good configuration

If input power exceeds the modules P1dB,
either reduce the input power, reconfigure the
module to increase P1dB or replace with a
more linear module (lower gain TX).

High
intermodulation
levels.

Gain adjustment set too high.
Incorrect manual or software

gain settings

Decrease TX gain setting.
Reset to factory default.

Or reset to known good configuration.

The ViaLiteHD range of RF transmitter and receiver modules are precision engineered and calibrated
for optimum performance and accuracy before dispatch.

In the event of any problems or queries arising with the equipment, please contact ViaLite
Communications or your local agent.

HRX-C-HB-1 C-BAND LINK HANDBOOK

30

6 FCC Approval

Information to the user of ViaLiteHD products:
For a Class A digital device or peripheral, the following instructions are furnished to the user. This

equipment has been tested and found to comply with the limits for a Class A digital device, pursuant to
part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful
interference when the equipment is operated in a commercial environment. This equipment generates,
uses, and can radiate radio frequency energy and, if not installed and used in accordance with the
instruction manual, may cause harmful interference to radio communications. Operation of this
equipment in a residential area is likely to cause harmful interference in which case the user will be
required to correct the interference at his own expense.

HRX-C-HB-1 C-BAND LINK HANDBOOK

31

7 Product warranty

ViaLite Communications guarantees its ViaLiteHD products, and will maintain them for a period of
three years from the date of shipment and at no cost to the customer. Extended warranty options are
available at the time of purchase.

Please note that the customer is responsible for shipping costs to return the module to ViaLite

Communications.
ViaLite Communications or its agents will maintain its ViaLiteHD products in full working order and

make all necessary adjustments and parts replacements during ViaLite Communications’ normal
working hours provided that the Customer will pay at the rates currently charged by ViaLite
Communications for any replacements made necessary by accident, misuse, neglect, wilful act or
default or any cause other than normal use.

Claims must be made promptly, and during the guarantee period.

IMPORTANT: ­Please contact both your selling agent and ViaLite Communications prior to returning any goods

for warranty or non-warranty repairs. Goods will not be accepted without a valid Goods Return
Number (GRN)

 PULSE POWER & MEASUREMENT LTD 2019.

NO PART OF THIS DOCUMENT MAY BE REPRODUCED OR TRANSMITTED IN ANY FORM WITHOUT PRIOR WRITTEN

PERMISSION.

PULSE POWER & MEASUREMENT LTD, 65 SHRIVENHAM HUNDRED BUSINESS PARK, SWINDON, SN6 8TY, UK.

TEL: +44 1793 784389 FAX: +44 1793 784391

EMAIL : SALES@VIALITE.COM WEBSITE : WWW.VIALITE.COM